Backbone and tryptophan side-chain dynamics of uniformly N-15-labeled Escherichia coli dihydrofolate reductase were determined for the binary folate complex. The N-15 T-1 and T-2 relaxation times and {H-1}-N-15 heteronuclear NOEs were measured for 118 protonated backbone nitrogen atoms. The generalized order parameter (S-2), the effective correlation time for internal motions (tau(e)), and the contribution to spin-spin relaxation through N-15 exchange broadening (R(ex)) were determined for each residue by model-free analysis. Back-calculation of the relaxation rates far each resonance showed that the calculated dynamical parameters accurately predict the experimental data. Diverse dynamical features were evident in the DHFR backbone. Six sites exhibited order parameters significantly below the weighted mean S-2 value (for the complex) of 0.81 +/- 0.002: residues G67 and D69 of the adenosine binding domain, and ''hinge'' residues K38 and V88, exhibited low S-2 (0.29 less than or equal to S-2 less than or equal to 0.6) and high tau(e) values (700 ps less than or equal to tau(e) less than or equal to 2 ns), as did sites within the beta A-alpha B loop and the beta F-beta G loop. Thus, large amplitude backbone motions, on the picosecond and nanosecond time scales, occurred at regions implicated in transition-state stabilization and in ligand-dependent conformational change. Significant R(ex) values (greater than or equal to 1 s(-1)) were determined for 45% of assigned resonances, many of which arise from residues surrounding the folate binding site. The mean S-2 values of the occupied folate binding site and the unoccupied NADPH binding site were similar, indicating the backbone of the latter is at least as conformationally restricted as that of the occupied folate site. We conclude that the observed time-dependent structural fluctuations of the binary complex are in fact associated with catalytic properties of the molecule.